Drinking-water supply device and method for controlling same

ABSTRACT

The present invention provides a method for controlling a drinking-water supply device, the method comprising: a first step of connecting a guide pipe of a case separable from a cabinet to form a channel through which water moves from the case to the cabinet; a second step of supplying the cabinet with sterile water electrolyzed by an electrolytic module included in the case; and a third step of supplying the cabinet with water which has not passed through the electrolytic module included in the case, wherein the sterilization water and the water are supplied to the cabinet from the case via the guide pipe in the second step and the third step.

CROSS-REFERENCE TO RELATED PATENT APPLICATIONS

This application is a U.S. National Stage Application under 35 U.S.C. § 371 of PCT Application No. PCT/KR2017/014454, filed Dec. 11, 2017, which claims priority to Korean Patent Application No. 10-2016-0167574, filed Dec. 9, 2016, whose entire disclosures are hereby incorporated by reference.

FIELD

The present invention relates to a drinking water supply device and a method for controlling the same, and more particularly, to a drinking water supply device and a method for controlling the same, which is capable of washing a path through which water passes in the drinking water supply device.

BACKGROUND

A drinking water supply device is a device that supplies drinking water to a user. The drinking water supply device may be a stand-alone device, or may constitute a part of other device.

For example, a water purifier is a device that allows original water supplied from a hydrant to pass through a separate filtering means and filters the original water in the filtering means to supply the filtered water to a user. Further, a device that supplies the filtered water as cold water or hot water to the user as needed may be regarded as the water purifier. The water purifier may be a stand-alone device from other electric home appliance.

Meanwhile, the drinking water supply device may constitute a part of an electric home appliance, such as a refrigerator. That is, water purified through the water purifier in the refrigerator may be supplied to the outside through the drinking water supply device. Water purified in the refrigerator may be cooled or frozen to allow cold water or ices to be supplied to the outside through the drinking water supply device.

The drinking water supply device is provided to supply drinking water to a user regardless of stand-alone from the other device. In other words, the drinking water supply device may be a device having a dispenser which is a space to which drinking water is supplied.

A variety of debris may be stuck to the path through which water passes in the drinking water supply device, whereby bacteria may breed. In this respect, it is required to clean the path.

An object of the present invention devised to solve one or more problems due to limitations and disadvantages of the related art is to provide drinking water supply device capable of cleaning a path through which water passes.

To achieve these objects and other advantages and in accordance with the purpose of the invention, a drinking water supply device comprises a cabinet; a purified water extraction valve provided in the cabinet, switching a path provided outside the cabinet to discharge purified water to a user; a cold water module provided in the cabinet, cooling externally supplied water; a cold water extraction valve switching a path for discharging water cooled by the cold water module to the user; a hot water module provided in the cabinet, heating externally supplied water; a hot water extraction valve switching a path for discharging hot water heated by the hot water module to the user; a case provided to be detached from the cabinet; an electrolysis module provided in the case, electrolyzing externally supplied water; and a guide pipe coupled to the case and detachably provided in the cabinet, moving water which has passed through the case to the cabinet, wherein the guide pipe is coupled to the cabinet when the path through which water moves in the cabinet is cleaned, and water which has passed through the case is supplied to the cabinet through the guide pipe regardless of whether the water passes through the electrolysis module.

Water which has not passed through the case may be supplied to the cabinet when any one of purified water, hot water and cold water is supplied to the user.

The cabinet maybe provided with a first controller for controlling the purified water extraction valve, the hot water extraction valve, and the cold water extraction valve.

The first controller may open the purified water extraction valve, the hot water extraction valve and the cold water extraction valve if the water which has passed through the case is supplied to the cabinet.

The cabinet may be provided with a water extraction valve switching a path where water is supplied to the user through the purified water extraction valve, the hot water extraction valve and the cold water extraction valve.

The water extraction valve may also be opened if the first controller opens the purified water extraction valve, the hot water extraction valve and the cold water extraction valve.

The case may include a first valve switching a path where water is supplied to the electrolysis module, and a second valve switching a bypass path so as not to supply water to the electrolysis module.

The case may be provided with a second controller for controlling the first valve and the second valve.

The second controller may open the first valve and close the second valve if the electrolysis module is driven.

The second controller may repeatedly open and close the first valve in a state that the second valve is closed.

The second controller may close the first valve and open the second valve if the electrolysis module is not driven.

The second controller may repeatedly open and close the second valve in a state that the first valve is closed.

The drinking water supply device may further comprise a divergence pipe for diverging externally supplied water into the purified water extraction valve, the cold water module and the hot water module.

Also, a method for controlling a drinking water supply device comprises a first step of connecting a guide pipe of a case detached from a cabinet to the cabinet to form a path through which water moves from the case to the cabinet; a second step of supplying sterile water electrolyzed by an electrolysis module included in the case to the cabinet; and a third step of supplying water which has not passed through the electrolysis module included in the case to the cabinet, wherein the sterile water and the water which has not passed through the electrolysis module are supplied from the case to the cabinet through the guide pipe in the second step and the third step.

The sterile water supplied to the cabinet in the second step may be discharged to the outside of the cabinet, and the water supplied to the cabinet in the third step may be discharged to the outside of the cabinet.

In the second step and the third step, a purified water extraction valve provided in the cabinet, switching a path provided outside the cabinet to discharge purified water to a user, a cold water extraction valve provided in the cabinet, switching a path for discharging cold water to the user, a hot water extraction valve provided in the cabinet, switching a path for discharging hot water to the user, and a water extraction valve provided in the cabinet, switching a path for supplying water to the user through the purified water extraction valve, the hot water extraction valve, and the cold water extraction valve may all be opened.

In the second step, a first valve provided in the case, switching a path where water is supplied to the electrolysis module may be opened and a second valve provided in the case, switching a bypass path so as not to supply water to the electrolysis module may be closed.

In the second step, opening and closing of the first valve may repeatedly be performed in a state that the second valve is closed.

In the third step, a first valve provided in the case, switching a path where water is supplied to the electrolysis module may be closed and a second valve provided in the case, switching a bypass path so as not to supply water to the electrolysis module may be opened.

In the third step, opening and closing of the second valve may repeatedly be performed in a state that the first valve is closed.

Advantageous Effects

According to the present invention, since a path through which water moves in a drinking water supply device is able to be cleaned, a sanitary condition may be improved.

Also, according to the present invention, since the path may be cleaned through two steps, a cleaning power may be improved. Since types of water supplied from the two steps are different from each other and pressures for supplying water are different from each other, the path through which the water passes may be washed more clearly.

Also, according to the present invention, since a water pressure supplied to the drinking water supply device may be increased during cleaning performed in the second step, a cleaning power may be improved due to a big pressure of the supplied water.

Also, according to the present invention, as the path through which water moves is simplified, cleaning may be performed under a simple control for opening a valve while washing water is passing through all paths through which water moves. Owing to the simplified path, a pressure is less reduced when water moves, whereby a cleaning power may be improved even in the case that a water supply system is only used.

Also, according to the present invention, since room temperature water is used during the second cleaning, hot water may be prevented from being extracted when a user extracts purified water or cold water after cleaning the path.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a view illustrating a drinking water supply device according to one embodiment of the present invention.

FIG. 2 is a view illustrating that a filter holder cover is detached.

FIG. 3 is a view illustrating a case according to one embodiment of the present invention.

FIG. 4 is a control block view according to one embodiment of the present invention.

FIG. 5 is a view illustrating a state that any one of purified water, hot water, and cold water is supplied to a user.

FIG. 6 is a control flow chart according to one embodiment.

FIG. 7 is a view illustrating a state of primary cleaning.

FIG. 8 is a view illustrating a state of secondary cleaning.

FIGS. 9 and 10 are views illustrating advantageous effects of one embodiment of the present invention.

DETAILED DESCRIPTION

Hereinafter, a preferred embodiment of the present invention through which the above objects can be implemented specifically will be described with reference to the accompanying drawings.

For clarification and convenience of description, size and shape of each element shown in the drawings may be exaggerated. Also, terms particularly defined considering configuration and functions of the present invention may be modified depending on a user, intention of an operator or practices. The terms used herein should be defined not simply by the actual terms used but by the meaning lying within and the description disclosed herein.

FIG. 1 is a view illustrating a drinking water supply device according to one embodiment of the present invention.

Hereinafter, a description will be given with reference to FIG. 1.

In one embodiment of the present invention, a drinking water supply device or liquid dispenser for selectively supplying purified water, cooled cold water, and heated hot water to a user is provided.

In one embodiment, the drinking water supply device may include a cabinet 10 forming external appearance, and a button 17 on the cabinet 10. The user may discharge water from the drinking water supply device by manipulating the button 17. The button 17 may be switched to various modes in such a way of varying a pushing time, varying pushing times, or the like. A plurality of buttons 17 may be provided such that each button may be switched to another mode when each button is pushed.

A water extraction unit or water dispenser 100 provided to be protruded from the cabinet 10, having a water extraction pipe for allowing water to move from the cabinet 10, a water extraction nozzle 110 formed to be downwardly protruded in the water extraction unit 100 and communicated with the water extraction pipe, and a handle 120 surrounding the outer circumference of the water extraction unit 100 are provided at the front of the cabinet 10.

The water extraction unit 100 may be disposed to enable rotation with respect to the cabinet 10, whereby the user may rotate the water extraction unit 100 clockwise or counterclockwise to a desired position. The water extraction unit 100 may be coupled to the cabinet 10 through a rotary unit 20. At this time, the rotary unit 20 may provide a structure in which the water extraction unit 100 can be rotated.

The water extraction unit 100 may be disposed to be protruded toward the front of the cabinet 10, whereby a container such as cup may easily be arranged without any restriction of the cabinet 10 when the user is supplied with water from the water extraction unit 100.

The water extraction nozzle 110 may be disposed to be downwardly exposed from the water extraction unit 100, whereby the user may easily recognize a portion where water is discharged out. Therefore, a container for receiving water may be arranged below the water extraction nozzle 110 to allow the user to be supplied with water.

Since the handle 120 may be disposed to surround the outer circumference of the water extraction unit 100, the user may rotate the water extraction unit 100 in a state that the user's hand is in contact with the handle 120.

Meanwhile, the handle 120 may be disposed to surround a lower portion of the water extraction unit 100, whereby an upper portion of the water extraction unit 100 may be exposed to the outside without being surrounded by the handle 120.

A lower end of the water extraction nozzle 110 is protruded to be lower than a lower portion of the handle 120, whereby the water extraction nozzle 10 may downwardly be exposed from the lower end of the water extraction unit 100 and the handle 120.

A tray 30 which can receive water dropped is provided at the lower portion of the water extraction unit 100. The tray 30 is provided with a space therein, and has a plurality of slits formed at an upper side thereof, whereby water may move into the tray 30 through the slits.

Referring to FIG. 2, a filter holder 300 in which filters 320 and 322 for purifying water discharged through the water extraction nozzle 110 are provided and a filter holder cover 310 for sealing the filter holder 300 from the outside are provided at the front of the cabinet 10.

The filter holder cover 310 is disposed on a front surface of the cabinet 10, whereby the user may easily approach the filter holder cover 310 as well as the water extraction unit 100.

The two filters 320 and 322 are provided in the filter holder 300, and are connected to each other by a connection pipe 330, whereby water may pass through the two filters 320 and 322 in due order.

The two filters are categorized into the first filter 320 and the second filter 322. Externally supplied water is filtered through the second filter 322 after passing through the first filter 320.

The first filter 320 may be a filter that includes a sediment filter and a free-carbon filter. First of all, debris having big particles, such as sand, soil and rust of a pipe, contained in service water is first removed from water supplied from a water supply system by the sediment filter.

The sediment filter is a filter manufactured of polypropylene of high density of 5 μm or less, and serves to protect all parts on a path of water, which has passed through this filter, and a membrane filter, which will be described later, by filtering debris and contaminant of 5 μm or more.

The sediment filter is a filter based on mechanical filtering, and has excellent effect to remove dust and complex particles existing in water.

Generally, lots of sand and iron particles which are not visible to the eye and other soil components are contained in service water. Also, sludge flowing along a pipe of a deteriorated water supply system or contaminants formed in a water supply pipe are plentifully contained in the service water.

These kinds of particles belong to a relatively large scaled contaminant group among whole contaminants contained in water, and are first filtered by the sediment filter. Then, filters subsequent to the sediment filter serve to filter smaller particles and fine components.

Since the membrane filter provided next to the first filter 320 serves to filter ultra-fine particles, if the membrane filter is directly exposed to relatively large scaled contaminants, its capability may be degraded in a moment, whereby the sediment filter may serve to protect a granule filter such as the membrane filter.

The free-carbon filter removes chemical materials harmful to a human body, such as, chlorine, cancer-causing agent, agricultural pesticide, and synthetic detergent by using an activated carbon absorption process.

The activated carbon contained in the free-carbon filter means a special carbon sintered at a high temperature using coconut peel, wood, coal, and the like as raw materials, and means a cluster of amorphous carbons formed during an activation process and well developed with micro-pores of a molecular size.

Although partial chemical adsorption occurs in a normal activated carbon by means of an absorbent having an internal surface area of 800 m3 to 1200 m3 per 1 g, most of absorption corresponds to physical absorption in which a functional group of a carbon atom existing in the activated carbon collects adsorbate molecules by applying attraction to liquid or gas in the vicinity.

The free-carbon filter has a function of making good taste of water in addition to a function of removing the smaller sized contaminants through adsorption subsequently to the sediment filter.

The water which has passed through the first filter 320 is guided to the second filter 322.

The second filter 322 includes a membrane filter and a post carbon filter.

The filter that may be used as the membrane filter is a reverse osmosis (RIO) filter, a hollow fiber membrane filter (UF) or the like.

The hollow fiber membrane filter of the membrane filter is a porous filter having several tens to several hundreds of nanometer (mm) sized pores, and removes contaminants existing in the water by allowing only the water to pass through innumerable fine pores distributed on a membrane surface.

A hollow fiber which forms a hollow fiber membrane of the hollow fiber membrane filter means a cluster of thread-like hollow filter fibers.

Although a reverse osmosis (RIO) type water purifier has been mainly used in recent years, the hollow fiber membrane filter serves to make up for a drawback of the reverse osmosis (R/O) type filter that fails to remove mineral in the water.

Also, the hollow fiber membrane filter has an advantage in that it is able to be operated even by a natural pressure of the water supply system not a pump of an artificial high pressure. Therefore, the hollow fiber membrane filter can make sure of a certain water flow and has an advantage in that blocking of the filter is little generated, unlike the RIO type filter.

The post carbon filter may remove unpleasant taste and smell, color, etc. which remain in the purified water, to enhance purity of water. The post carbon filter has an activated carbon therein in the same manner as the free-carbon filter.

In this embodiment, two filters are physically used, and each filter performs two functions. Therefore, the water which has passed through the first filter 320 and the second filter 322 is filtered by fully passing through four filters, whereby the purified water from which debris is filtered may be provided to the user.

FIG. 3 is a view illustrating a case according to one embodiment of the present invention.

The case 400 is provided to be detached from the cabinet 10. Therefore, the case 400 is not connected to the cabinet 10 when the user is supplied with purified water, hot water and cold water through the drinking water supply device. Therefore, the case 40 does not perform a separate function.

A guide pipe 440 is provided at a portion where water is extracted from the case 400, whereby the guide pipe 440 is connected to the cabinet 10 when a path through which water passes inside the cabinet 10 is cleaned.

At this time, the guide pipe 440 is detached from the case 400, and may be coupled to the case 400 if necessary. The guide pipe 440 may be provided to have a hose shape capable of being modified.

The case 400 is provided with an electrolysis module or electrolytic cell 420 for electrolyzing water supplied from the outside, and is also provided with a first valve or electrolysis valve 410 for switching a path of water supplied to the electrolysis module 420.

That is, if the first valve 410 opens the path, the water may be supplied to the electrolysis module 420 by passing through the first valve 410.

The electrolysis module 420 generates hypochlorous acid by electrolyzing the water supplied from the outside.

Since radical oxygen of hypochlorous acid is gaseous, it is stronger on oxidation than oxygen. Therefore, hypochlorous acid has an oxidizing power stronger than that of chlorine of a dried state, and is used for sterilization and bleaching as an oxidizing agent. As a result, the path through which water passes may be sterilized and cleaned by hypochlorous acid generated by the electrolysis module 420.

Also, a second valve or electrolysis bypass valve 430 for switching a bypass path is provided such that water is not supplied to the electrolysis module 420.

That is, if the second valve 430 opens the path, water is not supplied to the electrolysis module 420, and is discharged out through the guide pipe 440.

FIG. 4 is a control block view according to one embodiment of the present invention, and FIG. 5 is a view illustrating a state that any one of purified water, hot water, and cold water is supplied to a user.

Referring to FIGS. 4 and 5, the first filter 320 an the second filter 322 are detachably provided in the cabinet 10. The filter 320 and the second filter 322 serve to purify water supplied to the cabinet 10.

The cabinet 10 includes a purified or first water extraction valve 220 provided in the cabinet 10, opening or closing a path or first path for discharging water (at e.g., an unchanged temperature or a room temperature) purified by being supplied from the outside of the cabinet 10 to the user, a cold water module or first module 222 provided in the cabinet 10, cooling externally supplied water to a first temperature, a cold water or second extraction valve 240 for opening or closing a path or second path for discharging cold water cooled from the cold water module 222 to the user, a hot water module or second module 232 provided in the cabinet 10, heating externally supplied water to a second temperature, and a hot water or third extraction valve 230 for opening or closing a path or third path for discharging hot water heated from the hot water module 232 to the user. The paths may be formed by pipes.

Meanwhile, a divergence pipe 241 is provided to distribute the water which has passed through the first filter 320 and the second filter 322 into the purified water extraction valve 220, the cold water extraction valve 240, and the hot water extraction valve 230. Water may be introduced in a liquid receiving path.

Therefore, the water filtered by passing through the filters 320 and 322 may be distributed into the purified water extraction valve 220, the cold water module 222, and the hot water module 232 after passing through the divergence pipe 241. The divergence pipe 241 may simplify a moving path of water inside the cabinet 10, thereby providing water to the user during a normal operation by passing through each valve. That is, since a path where water is discharged may be divided into three types of paths by the divergence pipe 241, the paths may be simplified.

Also, the cabinet 10 is provided with a water extraction valve or discharge valve 210 provided in the cabinet 10, switching a path where the water which has passed through the purified water extraction valve 220, the hot water extraction valve 230 and the cold water extraction valve 240 is finally discharged to the user.

A connection pipe 242 where three paths are integrated into one path is provided before the water extraction valve 210, that is, among the purified water extraction valve 220, the cold water extraction valve 240, and the hot water extraction valve 230.

An inlet of the connection pipe 242 is provided with three paths, and its outlet is provided with one path, whereby the outlet of the connection pipe 242 is connected to the water extraction valve 210. Since three paths are integrated into one path, the path inside the cabinet 10 may be simplified.

That is, after the water entering the cabinet 10 is divided into three paths through the divergence pipe 240, the three paths are integrated into one path by the connection pipe 242. Therefore, each path is simplified, and washing water inside the path may move to all paths where water moves.

If the purified water extraction valve 220 and the water extraction valve 210 are opened together, the purified water which has passed through the purified water extraction valve 220 may be provided to the user.

If the hot water extraction valve 230 and the water extraction valve 210 are opened together, the hot water which has passed through the hot water extraction valve 230 may be provided to the user.

If the cold water extraction valve 240 and the water extraction valve 210 are opened together, the cold water which has passed through the cold water extraction valve 240 may be provided to the user.

The cold water module 222 performs a function of cooling water. Therefore, the cold water module 222 may include a cooling cycle including a compressor, an evaporator, etc. Unlike this case, water may be cooled using a thermoelectric element. In this embodiment, various devices may be adopted for the cold water module 222 to cool water.

The first hot water module 232 performs a function of heating water. Therefore, the hot water module 232 may include a heater, etc. In this embodiment, various devices may be adopted for the hot water module 232 to heat water.

Since the water extraction valve 210 includes a two-way valve, water which has passed through the water extraction valve 210 may be discharged to the outside through a separate drain line without being provided to the user. That is, if the water extraction valve 210 closes a path for supplying water to the user and opens the drain line, water is discharged to the outside of the cabinet 10 through the drain line.

The cabinet 10 is provided with a first controller 200 for controlling the water extraction valve 210, the purified water extraction valve 220, the hot water extraction valve 230, the cold water extraction valve 240, the cold water module 222, and the hot water module 232. The first controller 200 may perform a control operation based on various operations such as an operation of a user who pushes the button 17. In addition, the first controller 200 may control each element in accordance with a control algorithm that is already input.

The case 400 is provided with a second controller 450 for controlling the first valve 410, the second valve 430, and the electrolysis module 420.

The electrolysis module 420 may electrolyze water which has passed through a pipe, including two electrodes (positive(+) pole and negative(−) pole) exposed to the pipe, thereby generating sterile water.

The second controller 450 also performs a control operation in accordance with the user's pushing operation. If the user performs a certain operation, the second controller 450 may control each element in accordance with a control algorithm that is already input.

The operation of supplying any one of purified water, hot water and cold water to a user will be described with reference to FIG. 5.

When any one of purified water, hot water and cold water is supplied to a user, water which has not passed through the case 400 is supplied to the cabinet 10. That is, the case 400 is not involved in the operation of the cabinet 10, and the case 400 does not perform a function.

Therefore, original water such as tap water is supplied to the cabinet 10.

Water externally supplied to the cabinet 10 passes through the first filter 320 and the second filter 322, and is divided through three paths by the divergence pipe 240.

If the user desires to extract purified water, the first controller 200 opens the purified water extraction valve 220 and the water extraction valve 210. Therefore, the user may be supplied with the purified water through the water extraction nozzle 110. The water which has passed through the divergence pipe 240 passes through the purified water extraction valve 220 and then is guided to the water extraction nozzle 110 through the connection pipe 242.

If the user desires to extract hot water, the first controller 200 opens the hot water extraction valve 230 and the water extraction valve 210. At this time, the hot water module 232 may be driven to heat water. Therefore, the user may be supplied with the hot water through the water extraction nozzle 110. The water which has passed through the divergence pipe 241 passes through the hot water extraction valve 230 and then is guided to the water extraction nozzle 110 through the connection pipe 242.

If the user desires to extract cold water, the first controller 200 opens the cold water extraction valve 240 and the water extraction valve 210. At this time, the cold water module 222 may be driven to make water cold. Therefore, the user may be supplied with the cold water through the water extraction nozzle 110. The water which has passed through the divergence pipe 240 passes through the cold water extraction valve 240 and then is guided to the water extraction nozzle 110 through the connection pipe 242.

FIG. 6 is a control flow chart according to one embodiment. According to one embodiment, the cabinet 10 and the case 400 are connected to each other by the guide pipe 440 (S10). Therefore, a path where water moves from the case 400 to the cabinet 10 may be formed.

A cleaning operation may include a primary cleaning step and a secondary cleaning step. Primary cleaning is performed (S20), and then secondary cleaning (S30) is performed. In this embodiment, cleaning is performed twice, and kinds of washing water used for each cleaning are different from each other, and their supply modes are different from each other, whereby the path where water moves in the cabinet 10 may cleanly be washed.

FIG. 7 is a view illustrating a state of primary cleaning.

Referring to FIG. 7, the first filter 320 and the second filter 322 are detached from the cabinet 10. Since the first filter 320 and the second filter 322 are detachably provided in cabinet 10, water does not leak to the portion from which the first filter 320 and the second filter 322 are detached, even though the first filter 320 and the second filter 322 are detached from the cabinet 10.

The first controller 200 opens all of paths of the water extraction valve 210, the purified water extraction valve 220, the hot water extraction valve 230 and the cold water extraction valve 240 during the primary cleaning. As all of the valves of the cabinet 10 open the paths, the washing water supplied to the cabinet 10 may pass through the path through which water passes in the cabinet 10.

Also, since the first controller 200 does not drive the cold water module 222 and the first hot water module 232, water passes without being cooled or heated.

The second controller 450 drives the electrolysis module 420 during the primary cleaning. The second controller 450 opens the path of the first valve 410 and closes the path of the second valve 430.

Therefore, the water supplied to the cabinet 10 is sterile water electrolyzed by the electrolysis module 420.

At this time, the second controller 450 may periodically open and close the path of the first valve in a state that the path of the second valve 430 is closed. For example, the first valve 410 may be opened and closed at an interval of 1 second, whereby pulsation may be generated in the water passing through the first valve 410.

As a water pressure of water moving in accordance with switching of the path of the first valve 410 is changed, a speed of water is changed without flowing at a certain speed when passing through the path, whereby a cleaning power may be improved.

The first filter 320 may be disposed in the path for supplying water to the case 400. That is, before water is supplied to the case 400, the water is filtered by the first filter 320, whereby elements arranged in the case 400 may be prevented from being contaminated.

The sterile water electrolyzed by the electrolysis module 420 is supplied to the cabinet 10 through the guide pipe 440.

That is, if the electrolysis module 420 is driven, the second controller 450 opens the first valve 410 and closes the second valve 430, whereby the water is guided to the electrolysis module 420.

The sterile water guided by the guide pipe 440 moves to all paths where water moves in the cabinet 10, through the divergence pipe 241, and passes through the connection pipe 242. Therefore, all paths where water move may be maintained at a heated state by the hot water.

Since the valves 210, 220, 230, and 240 provided in the cabinet 10 are all opened by the first controller 200, the sterile water continues to be discharged through the water extraction nozzle 110. At this time, the sterile water which is discharged is water used when the inside of the cabinet 10 is cleaned.

In this embodiment, since the sterile water supplied to the cabinet 10 though the guide pipe 440 is supplied to all paths of the cabinet 10, all paths of the cabinet 10 may be cleaned, whereby cleanliness may be improved. That is, since the path supplied to the divergence pipe 241 is diverged into paths for supplying purified water, cold water and hot water, the inside of the cabinet 10 may be cleaned by the sterile water supplied from the electrolysis module 420.

Meanwhile, the water supplied to the cabinet 10 may be discharged to the outside through the water extraction nozzle 110 while passing through the water extraction valve 210, or may be discharged through a drain pipe which is separately provided. The water may be discharged to the outside of the cabinet 10 through any one of the water extraction nozzle 110 and the drain pipe.

FIG. 8 is a view illustrating a state of secondary cleaning.

Referring to FIG. 8, the second controller 450 closes the first valve 410 and opens the second valve 430 during the secondary cleaning. The second controller 450 does not drive the electrolysis module 420.

Therefore, water supplied to the case 400 is not sterile water electrolyzed by the electrolysis module 420. That is, the water supplied to the case 400 is different from the sterile water used during the primary cleaning. However, since the water is filtered through the first filter 320 during the secondary cleaning, the water does not contaminate the inside.

Since the water supplied to the case 400 passes through the first filter 320 only, a water pressure of water discharged from the case 400 through the guide pipe 440 is not reduced significantly.

Therefore, the path inside the cabinet 10 may cleanly be washed by a pressure of water discharged by passing through the guide pipe 440. If the second filter 322 is disposed at the front of the case 400, a water pressure of water may significantly be reduced in view of filtering characteristic of the second filter 322. However, since the first filter 320 is only applied to this embodiment, it is possible to make sure of a sufficient water pressure for cleaning the inside of the cabinet 10.

At this time, since the valves inside the cabinet 10 are all opened, the water supplied to the cabinet 10 is discharged through the water extraction nozzle 110.

In the same manner as the primary cleaning, the water supplied through the guide pipe 440 is supplied to all paths where water moves inside the cabinet 10 during the secondary cleaning, whereby all of the paths inside the cabinet 10 may be cleaned.

Meanwhile, in a state that the first valve 410 is closed, opening and closing of the second valve 430 may repeatedly be performed during the secondary cleaning. Therefore, the water supplied to the cabinet 10 through the guide pipe 440 may have pulsation. For example, if the second valve 430 is opened and closed at an interval of 1 second, the water passing through the inside of the cabinet 10 is repeatedly supplied or not at an interval of 1 second. As a water pressure of the path through which water passes is changed, the amount of water flowing along the path is changed, whereby a cleaning power for the path may be improved.

That is, a water flow of water is changed due to pulsation, and debris on an inner wall of the path may easily be removed and discharged to the outside.

Even in case of the secondary cleaning, the water supplied to the cabinet 10 is guided to the connection pipe 242 after passing through the divergence pipe 240, whereby the water may be discharged to the outside of the water extraction valve 210. At this time, the washing water may be discharged to the outside of the cabinet 10 through any one or both of the drain pipe and the water extraction nozzle 110.

FIGS. 9 and 10 are views illustrating advantageous effects of one embodiment of the present invention.

In detail, FIG. 9 illustrates advantageous effects when sterile water is converted to pulsation wave during primary cleaning.

View (a) of FIG. 9 illustrates an experimental result indicating that sterile water electrolyzed by the electrolysis module is used during the primary cleaning and room temperature water which is not electrolyzed by the electrolysis module is used during secondary cleaning. A removal rate of bacteria stuck to the path is 99.23%.

View (b) of FIG. 9 illustrates an experimental result indicating that sterile water electrolyzed during the primary cleaning is converted to a pulsation wave having pulsation and room temperature water which is not electrolyzed by the electrolysis module is used during the secondary cleaning. A removal rate of bacteria stuck to the path is 99.83%. In comparison with ‘a’, an improvement effect of 78% has been obtained in ‘b’.

According to the experiment of FIG. 9, it is noted that a cleaning power is improved if the path through which water passes is repeatedly opened and closed to generate pulsation in the case that sterile water electrolyzed during the primary cleaning is used.

FIG. 10 illustrates an experimental result indicating that pulsation is generated during the primary cleaning and water is supplied to the cabinet without through the electrolysis module during the secondary cleaning.

View (a) of FIG. 10 illustrates an experimental result indicating that sterile water electrolyzed by the electrolysis module is used during the primary cleaning and room temperature water which is not electrolyzed by the electrolysis module is used during secondary cleaning. Water used during the secondary cleaning passes through the electrolysis module but is not electrolyzed because the electrolysis module is not driven. A removal rate of bacteria stuck to the path is 99.14%.

View (b) of FIG. 10 illustrates an experimental result indicating that sterile water electrolyzed by the electrolysis module is used during the primary cleaning and room temperature water which is not electrolyzed by the electrolysis module without passing through the electrolysis module is used during the secondary cleaning. In ‘b’ of FIG. 10, since the water used during the secondary cleaning is bypassed without passing through the electrolysis module, a pressure of externally supplied water is not reduced as compared with ‘a’. Therefore, a water pressure of the water used during the secondary cleaning is higher than that of ‘a’. A removal rate of bacteria stuck to the path is 99.68%.

It is noted from the experimental result of ‘b’ in FIG. 10 that an improvement effect of 63% as compared with ‘a’ is obtained.

View (c) of FIG. 10 illustrates an experimental result indicating that sterile water electrolyzed by the electrolysis module is used during the primary cleaning and room temperature water which is not electrolyzed by the electrolysis module without passing through the electrolysis module is used during secondary cleaning. In ‘b’ of FIG. 10, since the water used during the secondary cleaning is bypassed without passing through the electrolysis module, a pressure of externally supplied water is not reduced as compared with ‘a’. Therefore, a water pressure of the water used during the secondary cleaning is higher than that of ‘a’.

Also, the path through which water moves is switched by the electrolysis module at an interval of 1 second during the primary cleaning, whereby pulsation of the water discharged from the electrolysis module has been generated.

That is, pulsation has been generated for the electrolyzed sterile water during the primary cleaning, and a water pressure of water has been prevented from being deteriorated by allowing the water not to pass through the electrolysis module during the secondary cleaning. In this experimental result, a removal rate of bacteria stuck to the path is 99.87%.

Therefore, it is noted from the experimental result of ‘c’ that ‘c’ has been improved by 85%, approximately, as compared with ‘a’.

In this embodiment, there is a change in kinds of washing water used for cleaning of two steps and supply methods and pressures of washing water, whereby a cleaning power for the path of the cabinet may be improved.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit and essential characteristics of the invention. Thus, the above embodiments are to be considered in all respects as illustrative and not restrictive. The scope of the invention should be determined by reasonable interpretation of the appended claims and all change which comes within the equivalent scope of the invention are included in the scope of the invention.

The present invention provides drinking water supply device capable of cleaning a path through which water moves. 

1. A liquid dispenser comprising: a liquid receiving path; a first module connected to the liquid receiving path to change a temperature of received liquid to a first temperature; a first valve to open or close a first path for discharging liquid at the first temperature; an electrolysis module to electrolyze liquid; and a guide pipe connecting the electrolysis module to the liquid receiving path, wherein, during a cleaning operation, liquid passes through the electrolysis module before being received in the first module, and wherein, during a normal operation, liquid bypasses the electrolysis module via a bypass path coupled to the guide path before being received in the first module.
 2. The liquid dispenser of claim 1, wherein liquid is supplied to the first module as liquid at the first temperature is discharged through the first valve.
 3. The liquid dispenser of claim 1, further including: a second module connected to the liquid receiving path to change a temperature of received liquid to a second temperature; a second valve to open or close a second path for discharging liquid at the second temperature; a discharge path connected to the first and second paths; and a discharge valve to open and close the discharge path to discharge liquid from the first and second paths.
 4. The liquid dispenser of claim 3, further including a first controller to control the first, second, and discharge valves and the first and second modules, wherein the first controller opens the first valve when liquid passes through the electrolysis module.
 5. The liquid dispenser of claim 4, further including: a third valve to open and close a third path for discharging liquid at a third temperature, wherein the first controller controls the third valve to be opened when liquid passes through the electrolysis module.
 6. The liquid dispenser of claim 4, wherein the first controller controls the discharge valve to be opened when the first controller opens the first and second valves.
 7. The liquid dispenser of claim 1, further including: an electrolysis valve to open and close an electrolysis path through which liquid is supplied to the electrolysis module; and an electrolysis bypass valve to open and close the bypass path through which liquid is supplied to the guide pipe without passing through the electrolysis module.
 8. The liquid dispenser of claim 7, further including a second controller to control the electrolysis valve, the electrolysis bypass valve, and the electrolysis module.
 9. The liquid dispenser of claim 8, wherein the second controller opens the electrolysis valve and closes the electrolysis bypass valve when the second controller controls the electrolysis module to be driven.
 10. The liquid dispenser of claim 9, wherein the second controller repeatedly opens and closes the electrolysis valve when the electrolysis bypass valve is closed and the electrolysis module is driven.
 11. The liquid dispenser of claim 8, wherein the second controller closes the electrolysis valve and opens the second electrolysis bypass valve when the second controller controls the electrolysis module to not be driven.
 12. The liquid dispenser of claim 11, wherein the second controller repeatedly opens and closes the electrolysis bypass valve during the cleaning operation when the electrolysis valve is closed, the electrolysis module is not driven.
 13. The liquid dispenser of claim 5, further comprising a divergence pipe connecting the liquid receiving path and the first and second modules; a cabinet enclosing the first and second modules, the first and second valves, the liquid receiving path, the first and second paths, the discharge path, and the discharge path; a case enclosing the electrolysis module, wherein the guide pipe is configured to selectively couple the case to the cabinet. 14-20. (canceled)
 21. A liquid dispenser comprising: a liquid receiving path; a first module configured to receive liquid from the liquid receiving path and dispense liquid at a first predetermined temperature; a valve provided on the liquid receiving path; a controller configured to control the valve to repeatedly open or close the liquid receiving path during a cleaning operation of the liquid dispenser.
 22. The liquid dispenser of claim 21, further comprising a second module configured to receive liquid from the liquid receiving path after it has passed through the valve and to dispense liquid at a second predetermined temperature.
 23. The liquid dispenser of claim 22, further including: a discharge valve for discharging liquid that has flowed through the first or second module; a filter to filter liquid, wherein liquid passing through the valve has passed through the filter.
 24. The liquid dispenser of claim 21, further comprising an electrolysis module connected to the liquid receiving path.
 25. The liquid dispenser of claim 24, wherein liquid received by the electrolysis module has passed through the valve.
 26. A liquid dispenser comprising: a supply valve configured to open or close a supply path; an electrolysis module provided on the supply path for electrolyzing water molecules; a discharge valve configured to open or close at least one discharge path to discharge water that has passed through the supply path; a controller configured to control the supply valve to open or close the supply path such that the supply path is repeatedly opened and closed.
 27. The liquid dispenser of claim 26, further comprising a module provided between the electrolysis module and the discharge valve to heat or cool liquid received from the supply path, wherein the heated or cooled liquid is discharged through the discharge valve. 